/Integrated Infrared Spectrometers for Consumer Applications

Integrated Infrared Spectrometers for Consumer Applications

Leuven | More than two weeks ago

Integration of thin-film photodetectors with flat optics for miniaturized NIR-SWIR spectrometers

Near-infrared (NIR) spectroscopy is a non-destructive analytical technique used to identify and quantify components in a sample by measuring the absorption of near-infrared light (700 – 2500 nm spectral range). This technique is employed across diverse industries including pharmaceuticals, agriculture, and food processing for tasks such as determining the nutrient content of soil, analyzing the composition of drugs, and assessing the quality of food products. There is strong motivation to integrate miniaturized NIR spectroscopic sensors into consumer products such as wearables and smartphones, which would provide consumers valuable information without the need for complex instrumentation and trained personnel. For example, on-skin measurements with such sensors could provide more information about our health compared to today’s wearable devices, which typically measure heart rate and oxygen saturation. Additionally, we could gain direct insights into the nutritional information of the food on our plates. However, bringing this technology to consumer products requires affordable and miniaturized devices, which poses challenges, particularly at wavelengths beyond 1000 nm where cheap and ubiquitous silicon-based photodetectors become ineffective due to silicon’s transparency. Thin-film photodiodes based on colloidal quantum dots (CQDs) have emerged as a promising approach to enable affordable sensors at longer wavelengths. CQDs are chemically synthesized nanocrystals with remarkable emissive and absorption properties, and they can be deposited in form of thin films over large areas. Our group has been developing this technology for over eight years, leveraging expertise from various domains including material science, semiconductors, micro/nanofabrication, and photonics. More recently, we patented and demonstrated a new approach for spectral sensing by combining our CQD photodiodes with another emerging technology – optical metasurfaces, which will be the foundation and a starting point for this PhD topic.

Topic

The goal of this PhD is to advance spectral sensing based on thin-film photodiodes, targeting high sensitivity, high spectral resolution and fabrication scalability which is necessary for consumer applications.  

This PhD therefore has two important pillars:

  1. Device design and process development for CQD photodiode fabrication, targeting high spectral resolution and sensitivity.
  2. Optical simulations (e.g. FDTD with Lumerical) of optical metasurfaces which are fabricated in imec’s cleanroom facilities.


The candidate

You are a highly motivated recent graduate holding a master’s degree in nano-engineering, physics, material science, chemistry, electrical engineering, or related. You have an interest in the processing of thin-film semiconductors, optical effects in such layers, and electrical and optical characterization. You will be expected to work safely in a lab environment and acquire necessary processing and characterization skills. It is expected that you will present results regularly.  You are a team player and have good communication skills as you will work in a multidisciplinary and multicultural team spanning several imec departments. Given the international character of imec, an excellent knowledge of English is a must.



Required background: Nano-engineering, physics, materials science or electrical engineering with strong affinity for device physics

Type of work: 30% modeling, 30% processing, 20% characterization, 10% design, 10% literature study

Supervisor: Jan Genoe

Daily advisor: Vladimir Pejovic

The reference code for this position is 2025-117. Mention this reference code on your application form.

Who we are
Accept marketing-cookies to view this content.
Cookie settings
imec inside out
Accept marketing-cookies to view this content.
Cookie settings

Send this job to your email